[1] Becchio, C., Corgnati, S., Kindinis, A. and Pagliolico, S. (2009) Improving Environmental Sustainability of Concrete Products: Investigation on MWC Thermal and Mechanical Properties. Energy and Buildings, 41, 1127-1134.
http://dx.doi.org/10.1016/j.enbuild.2009.05.013
[2] ACI Board Advisory Committee on Sustainable Development (2004) White Paper. ACI, Detroit.
[3] Mehta, K. (2001) Reducing the Environmental Impact of Concrete. Concrete International, 23, 61-65.
[4] Martin, N., Worrell, E. and Price, L. (1999) Energy Efficiency and Carbon Dioxide Emissions Reduction Opportunities in the US Cement Industry. Lawrence Berkeley National Laboratory, University of California.
[5] Martin, N., Worrell, E. and Price, L. (1999) Energy Efficiency and Carbon Dioxide Emissions Reduction Opportunities in the US Iron and Steel Sector. Lawrence Berkeley National Laboratory, University of California.
[6] Yehia, S. and Kashwani, G. (2013) Performance of Structures Exposed to Extreme High Temperature—An Overview. Open Journal of Civil Engineering, 3, 154-161. http://dx.doi.org/10.4236/ojce.2013.33018
[7] Hossain and Tarefder (2013) Effects of Moisture in Asphalt Concrete. Basic Research Journal of Engineering Innovation, 1, 16-25.
[8] US Department of the Interior, Bureau of Reclamation (1970) Fly Ash Increases Resistance to Sulfate Attack. Research Report No. 23, 5.
[9] Suprenant, BA. (1991) Testing for Chloride Permeability of Concrete. Concrete Construction.
[10] EAD (Environment Agency-Abu Dhabi). https://www.ead.ae/en/elibrary/